Dynamic transformations in the organization of the cellular microfilament system are the driving force behind fundamental biological processes such as cellular motility, cytokinesis, wound healing and secretion. Eukaryotic cells express a plethora of actin-binding proteins (ABPs) allowing cells to control the organization of the actin cytoskeleton in a flexible manner. These structural proteins were, not surprisingly, originally described as (major) constituents of the cytoplasm. However, in recent years, there has been a steady flow of reports detailing not only translocation of ABPs into and out of the nucleus but also describing their role in the nuclear compartment. This review focuses on recent developments pertaining to nucleocytoplasmic transport of ABPs, including their mode of translocation and nuclear function. In particular, evidence that structurally and functionally unrelated cytoplasmic ABPs regulate transcription activation by various nuclear (steroid hormone) receptors is steadily accruing. Furthermore, the recent finding that actin is a necessary component of the RNA polymerase II-containing preinitiation complex opens up new opportunities for nuclear ABPs in gene transcription regulation.Key words: actin-binding protein, actin, cytoskeleton, gene transcription, nucleus, steroid hormone receptor, transcription factor, transport
Nucleocytoplasmic TransportIn eukaryotic cells, the cytoplasm and nucleus are separated by the nuclear envelope. Trafficking of proteins and RNA molecules across this double membrane occurs via the nuclear pore complex, a large proteinaceous channel embedded in the nuclear membrane and composed of approximately 30 different proteins, termed nucleoporins (1). Protein transport is mediated by soluble transport receptors known as importins and exportins. These proteins recognize transport signals in their cargoes (Table 1) (2-4) and mediate translocation through the nuclear pore complex, primarily through interactions with nucleoporins. Although several other transport signals have been identified, targeting sequences in many cargoes of importin-b receptors still await identification.The best known nuclear export signal is a leucine-rich sequence that was first identified in the HIV-1 Rev protein (5,6) and protein kinase A inhibitor (7). These signals are recognized by the CRM1 receptor, a member of the importin-b family. Binding of CRM1 to leucine-rich export sequences is inhibited by leptomycin B, an antifungal antibiotic isolated from Streptomyces spieces (5,8), and has become a useful tool to identify
